Laser cooling at high density in deep far-detuned optical lattices

S. Lukman Winoto; Marshall T. DePue; Nathan E. Bramall; David S. Weiss

doi:10.1103/PhysRevA.59.R19

Laser cooling at high density in deep far-detuned optical lattices

S. Lukman Winoto, Marshall T. DePue, Nathan E. Bramall, David S. Weiss

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59 Scopus citations

Abstract

We report a way to overcome heating due to the reabsorption of scattered light when relatively many atoms are laser cooled at high density. A sample of [Formula Presented] atoms, with [Formula Presented] is loaded into a deep far-detuned one-dimensional optical lattice, which acts as a large volume three-dimensional (3D) trap. Polarization gradient cooling with a separate set of cooling beams is found to work well in this trap, populating the trap’s vibrational ground state with more than half the atoms. After cooling, the lattice is shut off adiabatically, leaving a still dense sample at 1.2 μK. We propose and demonstrate a generalization to a 3D lattice, which will allow many more atoms to be loaded into conservative light traps, and can greatly increase the initial phase-space density for loading magnetic traps.

Original language	English (US)
Pages (from-to)	R19-R22
Journal	Physical Review A - Atomic, Molecular, and Optical Physics
Volume	59
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevA.59.R19
State	Published - Jan 1 1999

All Science Journal Classification (ASJC) codes

Atomic and Molecular Physics, and Optics

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10.1103/PhysRevA.59.R19

Cite this

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abstract = "We report a way to overcome heating due to the reabsorption of scattered light when relatively many atoms are laser cooled at high density. A sample of [Formula Presented] atoms, with [Formula Presented] is loaded into a deep far-detuned one-dimensional optical lattice, which acts as a large volume three-dimensional (3D) trap. Polarization gradient cooling with a separate set of cooling beams is found to work well in this trap, populating the trap{\textquoteright}s vibrational ground state with more than half the atoms. After cooling, the lattice is shut off adiabatically, leaving a still dense sample at 1.2 μK. We propose and demonstrate a generalization to a 3D lattice, which will allow many more atoms to be loaded into conservative light traps, and can greatly increase the initial phase-space density for loading magnetic traps.",

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AU - Winoto, S. Lukman

AU - DePue, Marshall T.

AU - Bramall, Nathan E.

AU - Weiss, David S.

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N2 - We report a way to overcome heating due to the reabsorption of scattered light when relatively many atoms are laser cooled at high density. A sample of [Formula Presented] atoms, with [Formula Presented] is loaded into a deep far-detuned one-dimensional optical lattice, which acts as a large volume three-dimensional (3D) trap. Polarization gradient cooling with a separate set of cooling beams is found to work well in this trap, populating the trap’s vibrational ground state with more than half the atoms. After cooling, the lattice is shut off adiabatically, leaving a still dense sample at 1.2 μK. We propose and demonstrate a generalization to a 3D lattice, which will allow many more atoms to be loaded into conservative light traps, and can greatly increase the initial phase-space density for loading magnetic traps.

AB - We report a way to overcome heating due to the reabsorption of scattered light when relatively many atoms are laser cooled at high density. A sample of [Formula Presented] atoms, with [Formula Presented] is loaded into a deep far-detuned one-dimensional optical lattice, which acts as a large volume three-dimensional (3D) trap. Polarization gradient cooling with a separate set of cooling beams is found to work well in this trap, populating the trap’s vibrational ground state with more than half the atoms. After cooling, the lattice is shut off adiabatically, leaving a still dense sample at 1.2 μK. We propose and demonstrate a generalization to a 3D lattice, which will allow many more atoms to be loaded into conservative light traps, and can greatly increase the initial phase-space density for loading magnetic traps.

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Laser cooling at high density in deep far-detuned optical lattices

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